KR200369425Y1 - Automatic voltage controller - Google Patents

Abstract

The present invention relates to an AVC for driving a power transformer OLTC (On-Load Tap Changer), and a large display for viewing various information of the AVC, POWER, various errors, operation check (RAISE / LOWER, INT) , TIMER 1,2, LDC / Z, V Change 1,2, DVM), and LED to visually inform the display when a CPU error occurs, and a key button to freely set AVC correction values as key signals. Includes Menu / Exit, SEL, SET, UP, DOWN, mode switch for switching between Auto Mode and Manu Mode, and Reset switch for initializing the AVC system. A communication port includes a port for short-range communication with the ability to monitor the AVC status from outside by connecting a computer or to troubleshoot and correct data, and to display the AVC internal circuits and display errors. Display as character Alarm is given through and displays error only when it is malfunctioning. In addition to the constant monitoring function that automatically returns to the normal state upon recovery, the AVC's correction values (Z, LDC compensation, load center point, BAND WITH value, time delay value, etc.) can be reasonably calculated according to the characteristics of the line load. In addition, DSP processor and EVENT storage function are included to manage optimal voltage by applying.

Description

Transformer automatic voltage controller

The present invention relates to an AVC for driving a power transformer OLTC (On-Load Tap Changer), and in particular, to adjust the AVC correction values (Z, LDC compensation, load center point, BANDWITH value, time delay value, etc.) according to the characteristics of the line load. The present invention relates to a transformer automatic voltage regulator of transmission and substation equipment with various functions such as DSP processor and EVENT storage to reasonably calculate, apply, and manage the optimal voltage.

In recent years, the utility model registration No. 184832 proposed by the present inventors has expanded the function of the voltage regulator to change the transformer ratio of transformer according to the load fluctuation of the two-lane of the power system and added a number of convenience functions. Automatic voltage regulators have been developed.

That is, the existing AVC is equipped with a control unit that performs a control operation throughout the device, a keypad composed of a plurality of keys for selecting various function coefficients and setting values, an adjustment knob for changing various coefficient values and setting values, and the like. The control selection unit for selecting and operating an operation function, a communication module for communication connection between the system, and an optical insulation unit for converting into an electrical output by an optical element to drive the other electric circuit to one side of the control unit. A display unit for displaying the operation status of the device as a number or a letter, a relay driver having a function of connecting each power supply to operate each driver according to a selected function, and a voltage converter for converting an AC voltage to a DC voltage and a continuous analog A / D converter that converts the signal into encoded digital signal , There is a characteristic of the operation of the device is conveniently a state and a voltage adjustment condition enabling the observation and control.

The present invention was created by further reinforcing the above-mentioned contents. The purpose of the present invention is to adopt a 16-bit DSP processor so that the input amount can be stably measured, and the OLTC tap changer operation count can be memorized so that the OLTC replacement time can be easily predicted. By adding various functions such as EVENT storage function and AVC status monitoring, it provides transformer automatic voltage regulator differentiated from existing products.

1 is an internal control block diagram employing a DSP processor of the present invention AVC,

2 is an exemplary operation front view of the subject innovation AVC,

3 is a diagram illustrating an internal configuration of the rear terminal block of FIG. 2.

<Description of the code | symbol about the principal part of drawing>

10: Arithmetic Digital Relay

11: DSP, 30: communication device,

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an internal control block diagram employing a DSP processor of the AVC of the present invention, FIG. 2 is an exemplary front view of an operation of the AVC of the present invention, and FIG. 3 is an internal configuration diagram of the rear terminal block of FIG. 2.

As shown in FIG. 2, the external structure of the inventive AVC is a large display capable of viewing various types of information of the AVC, and includes power, various errors, and operation check (RAISE / LOWER, INT, TIMER 1,2, LDC / Z, V Change 1,2, DVM), and a LED that visually informs the display when a CPU error occurs.

In addition, as a key button that can freely set the correction values of the AVC as a key signal, a mode switching switch for switching between Menu / Exit, SEL, SET, UP, DOWN, and Auto Mode and Manual Mode. It includes a reset switch that initializes the system of AVC, and 30 is an RS-232 communication port, which is connected to a computer to monitor AVC status from outside or to troubleshoot and correct data. Included.

In addition, the constant monitoring function monitors the main elements of the AVC and monitors the errors. Alarms are provided through the display as numerical values and characters. When the system malfunctions, it displays an error only and automatically returns to normal status when it recovers normally.

2 is an internal configuration diagram of FIG. 1, and 10 is an arithmetic digital relay means, and the calculation algorithm is based on a sine wave of a power system fundamental frequency (60 Hz), so that frequency components other than the sine wave are included in the input waveform. If an error occurs in the calculation result, it is difficult to accurately determine the fault. Therefore, an analog filter that cuts off some frequencies except sine wave is adopted first, and then the 16-bit A / D converter converts the input analog signal into a digital signal. In the sample hold circuit inside the A / D converter, a 16-bit DSP processor that samples the analog value output from the analog filter at regular time intervals and performs computation processing on the quantized digital quantity is programmed. do.

The output contact shown in FIG. 3 includes OLTC TAP Changer Raise / Lower (relay output 1a), alarm contact OVER VOLTAGE (relay output 1a), UNDER VOLTAGE (relay output 1b), and OVER CURRENT (relay output) for OLTC contact operation management. Output 1a), error contact relay fault, and relay output 1b.

As an external display and key input unit, it is composed of the configuration as described in FIG. 1 above, but a large-capacity liquid crystal panel is adopted, and is designed to easily read various numerical values and correction values. It is provided to be.

As a program memory device, two high speed 16Bit SRAMs are used to store instruction code data and table data using one 8-bit flash memory that is connected and operated by a 32-bit data bus. This flash memory data is used after being moved to the SRAM area by a boot operation or the like. It is also used as a 16-bit data bus using two high-speed 8-bit SRAMs as another memory for storing data by data backup even when the power is turned off.

It is a communication device of 30. It controls two communication types, RS-232 (front) and RS-485 (rear), and RS-485 communication is monitored by DNP communication in SCADA system by network. The 232 has a telecommunication function to read or store all of the AVC information using a computer. In particular, it reads FAULT RECODER information (operation time, voltage, current, operation cause, etc.) of AVC and enables accurate failure cause identification and analysis using AVC's failure analysis program.

The digital arithmetic processing unit (control unit) is a CPU that performs DSP operation with a central processing unit, a ROM embedded in the CPU that stores a program and its operation procedure, A / D conversion data and temporary data in an analog input unit. It consists of a RAM for storing data, and is connected by a line for transmitting data control information such as a bus. Here, the input signal receives a voltage, a correction value, or the like, performs arithmetic processing, and outputs the result to a memory unit or an output unit.

Since the unsigned code RTCC must calculate and maintain the date and time even when the power is turned off, it is preferable to use the backup power of the battery backup circuit in the same manner as the RAM.

The above configuration is only one embodiment of the present invention and can be changed and modified as much as possible within the scope of the present invention.

The AVC of the present invention configured as described above is equipped with an automatic constant monitoring function to monitor the abnormality of the AVC, and the monitoring range is DSP, CPU, memory (ROM. RAM) and correction unit, signal input / output unit, A / D The converter section includes a power supply circuit.

In addition, the event EVENT is converted into data desired by the user, and when the event state changes, the corresponding data is transmitted to the communication device including time information. The supervisory elements include voltage, current and AVC Fail. In particular, the value converted from the analog signal acquired from the power equipment to digital should be transmitted. The measurement elements are voltage, current, and phase.

The AVC has a record for storing a fault record in case of a fault, and when a new fault occurs, the old record is deleted and a new record is stored. The relay must be able to store more than a certain number of fault records (up to 110) for fault analysis, and the minimum length of each fault record is at least 1 second. The fault record contains all analog and digital inputs and outputs for the AVC. If AVC power supply is interrupted, the fault data stored in case of failure should be kept for at least a certain period from the time when the DC supply is interrupted, and the correction value etc. does not change permanently. Here, the software for failure analysis can be mounted on a personal computer or HMI device for failure analysis, and the operating time, voltage, current, and cause of operation of the analog signal are recorded to check the ambient conditions at the time of AVC operation.

It has HMI and telecommunication function. It can be used by directly connecting RS-232C status, fault data acquisition, analysis and correction using portable PC, and also through network connection through RS-485 port. Make it possible.

On the other hand, it is effective to refer to OLTC operation and lifespan by counting the number of RAISE / LOWER operation of AVC based on the date when AVC is installed on site.

The operation of the AVC according to the menu selection by the display and key operation will be described briefly as follows. First, when the initialization is performed according to the power on, self-diagnosis is performed to determine whether the main component is abnormal. At this time, if the abnormality is detected, the corresponding abnormal element is displayed (for example, a memory fault: ROM / RAM / CLOCK, A /). D Fault, etc.) If normal, the current voltage and current monitoring status displays the current time and the magnitude of the input voltage current in real time, and generates the corresponding event or shows the result according to the result of the calculated data. Becomes 1 Here, the displayed value is time, PT input voltage, CT input current, load center point management voltage, upper / lower limit% bandwidth ratio of voltage to be managed, timer for OLTC control, and voltage (V3) deviation from the voltage to be managed (deviation). ), And display status messages at the top of the display when errors and events occur.

If the alarm occurs after step 1, it is generated according to each alarm type, that is, OVER CURRENT, OVER VOLTAGE, UNDER VOLTAGE, and UNDER VOLTAGE are executed. Alarms are automatically cleared when detected.

* In case of a failure that AVC cannot operate normally after step 1, it shows the factors such as DC FAILURE (When DC input voltage is less than about 80V), SV.FAULT (Set value is changed or not set without normal process. Out of range).

In addition, you can check the current set value, which shows the set data each time you press the UP or DOWN key in the NORMAL mode described above. While in the NORMAL MODE, the compensation menu is divided into LDC and Z-COMP. When LDC is selected, the UR and UX correction values and Z-COMP can check the Z-LIMIT / Z-RATIO values. .

If you press MENU S / W in the NORMAL state, the main menu screen appears. SETTING: Setting various information of AVC, DVM, AVC RUN SELECT, EVENT INFO: Checking EVENT output information for OLTC control, SYSTEM: Necessary for operation of AVC Various information setting, OLTC TAP COUNTER: RAISE, LOWER output count

The AVC (load center voltage management) is 1, EDIT SELECT (operation mode selection) 2, REF.V (AVC reference voltage setting), 3, BAND WITH (AVC reference voltage bandwidth setting) 4, T MODE (AVC of Output signal operation time set to DELAY1, DELAY, reverse branch (INT) setting 5, DELAY 1 (correction of reverse branch operation time and timer operation time) 6, DELAY 2 (delay 2 automatically turns off if timer is set to reverse branch) 7) COMP (line voltage drop compensation method selection LDC-COMP, Z-COMP) 8, Z-COMP correction When selecting LDC-COMP with Z-RATIO UR value setting item conversion 9, Z-COMP correction Z UX value setting item automatic conversion when LDC-COMP is selected with LIMIT 10, UNDER V (Lower limit monitoring alarm output of PT input voltage 11, OVER V (Lower limit monitoring alarm output of PT input voltage) 12, OVER I (CT input voltage Upper limit monitoring alarm output) 13, V CHANG1 (remote control of reference voltage of item 2 using VOLT CHANGE) 14, V CHANG2 (same function of # 13)

When the DVM (outgoing terminal voltage management) is used in parallel with the DVM operation and the AVC operation, the RAISE or LOWER operation is performed by the DVM and the output is sent to the OLTC TAP Changer. The count will be performed. 1, BAND + (Set the upper limit of substation output voltage) 2, BAND- (Set the lower limit of output terminal voltage) 3, TIME (correct operation time of AVC during DVM operation) 4, DVM (DISABLE: Do not operate DVM, ENABLE: DVM Driving in parallel with AVC)

As discussed above, the present invention enables 16-bit DSP processor to measure the input quantity stably, and it is possible to easily predict the OLTC replacement time by remembering the number of OLTC tap changer operation, EVENT storage function and communication. Various functions such as AVC status monitoring through devices are added, and it can be seen that it has different characteristics than existing products.

Claims (1)

Large display for viewing various information of AVC, POWER, various errors, operation check (RAISE / LOWER, INT, TIMER 1,2, LDC / Z, V Change 1,2, DVM), CPU error The LED is used to visually inform the display together with the display when it is generated, and is used as a key button for freely setting the correction values of the AVC as a key signal, such as Menu / Exit, SEL, SET, UP, DOWN, and Auto Mode. And a mode switch for manual mode (Manu Mode) switching, and a reset switch for initializing the system of the AVC.It can be connected to a computer as a communication port to monitor AVC status from outside or to troubleshoot and correct data. It includes a short-range communication port with the function to monitor and display the main elements of the AVC and monitor the error.The alarm is displayed through the display as numerical value and letter. In the case of the automatic voltage regulator (AVC) for changing the transformer ratio of the transformer according to the load fluctuations of the second line of the power system is equipped with a constant monitoring function that automatically returns to the normal state when recovering, First of all, it adopts an analog filter that cuts off some frequencies except sine wave and uses 16Bit A / D converter that converts the analog signal into digital signal afterwards.Sample Hold inside A / D converter An arithmetic digital relay means employing a 16-bit DSP processor that performs sampling processing of the quantized digital quantity by sampling the analog value output from the analog filter at regular intervals in the circuit, and OLTC for OLTC contact operation management. Includes TAP Changer Raise / Lower (Relay Output 1a), Alarm Contact OVER VOLTAGE (Relay Output 1a), UNDER VOLTAGE (Relay Output 1b), OVER CURRENT (Relay Output 1a), and Error Contact Relay Fault (Relay Output 1b). Accurate high accuracy using AVC failure analysis program by reading output contact means and FAULT RECODER information (operation time, voltage, current, cause of operation, etc.) of AVC Attribution and analyzing the EVENT saved automatically by the transformer voltage regulating device characterized by comprising means enabling.